Construction of Aramid Nanofiber-Based Interphase by In Situ Controlled Polymerization and Mechanism for Interfacial Reinforcement of Aramid Fiber Composites

Construction of Aramid Nanofiber-Based Interphase by In Situ Controlled Polymerization and Mechanism for Interfacial Reinforcement of Aramid Fiber Composites

Aramid Fiber Reinforced Composites (AFRCs) rely on a strong interfacial bond between aramid fiber and polymeric matrix to yield the high strength and toughness expected by a composite material. But they tend to have poor interfacial bonding between the chemically inert fibers and the matrix polymers...

وصف كامل

محفوظ في:
التفاصيل البيبلوغرافية
المؤلف الرئيسي: Wei Guo (86150) (author)
مؤلفون آخرون: Shifan Lu (22780046) (author), Zhiping Zhao (779373) (author), Changmei Sun (1657441) (author), Ying Zhang (40767) (author), Rongjun Qu (1657435) (author), Ying Wang (11406) (author)
منشور في: 2025
الموضوعات:
Biophysics
Biochemistry
Biotechnology
Biological Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
Physical Sciences not elsewhere classified
nanoscale surface modifiers
functional fillers within
tailor interfacial properties
gradient interfacial region
situ controlled polymerization
improves tensile strength
dual reinforcement approach
chemically inert fibers
strong interfacial bond
poor interfacial bonding
bulk fiber structure
nr gives rise
aramid fiber composites
interfacial reinforcement
aramid fibers
strong interphase
step polymerization
hydrogen bonding
aramid fiber
aramid nanofiber
based composites
synthesized directly
scale design
scalable route
rigid three
polymeric matrix
optimal conditions
nr matrix
natural rubber
mechanical integrity
matrix polymers
high strength
force increases
excellent dispersion
excellent compatibility
dimensional network
composite material
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الوصف
الملخص:Aramid Fiber Reinforced Composites (AFRCs) rely on a strong interfacial bond between aramid fiber and polymeric matrix to yield the high strength and toughness expected by a composite material. But they tend to have poor interfacial bonding between the chemically inert fibers and the matrix polymers. In order to construct a strong interphase in aramid fiber composites, we present a novel interphase construction strategy that leverages in situ synthesized aramid nanofibers (ANFs), which are synthesized directly in natural rubber (NR) via a one-step polymerization. The ANFs then, in constructing the AFRCs, serve both as functional fillers within the NR matrix and as nanoscale surface modifiers for aramid fibers and fabrics. The ANFs exhibit compact morphologies and excellent dispersion, and they form a rigid three-dimensional network in NR that improves tensile strength, modulus, and toughness. Through dip-coating, ANFs are anchored onto aramid surfaces, which significantly increases surface roughness and functional group density without altering the bulk fiber structure. The excellent compatibility between ANFs and NR gives rise to a gradient interfacial region that enhances stress transfer via physical entanglement and hydrogen bonding. Multiscale characterization reveals improved interface behavior and mechanical integrity, and under the optimal conditions, the pull-out force increases by 207.4% and 286.8% for the fiber-based and fabric-based composites, respectively. This dual reinforcement approach is a scalable route to tailor interfacial properties and lays the groundwork for the cross-scale design of high-performance aramid fiber composites.

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